Why muons at the Intensity Frontier?

A STUDY OF MUONS CAN ANSWER THE FOLLOWING QUESTIONS:

Muons could provide the path to unveiling hidden physics phenomena. In particular, physicists hope that muons will shed light on these questions:

Are there undiscovered principles of nature: new symmetries, new physical laws?

Do all forces that dictate particle interactions merge into one force, called a grand unification, at higher energy scales?

Why are there so many kinds of particles?

If charged lepton flavor violation occurs, is it related to the flavor violation seen with quarks? Or is it due to new phenomena at the Terascale, an energy region named for the tera, or million million, electronvolts of energy needed to access it?

Physicists can study muons and learn more about their role in the universe by making huge numbers of them with a high-intensity accelerator and by building a set of magnets that increases the
chance of observing muon-to-electron conversion. The proposed Mu2e experiment will provide unprecedented sensitivity to this conversion process and will offer a new window on physics beyond the
Terascale, including unification.

Particle physics has been very successful in creating the Standard Model, a theoretical framework that describes all known particles and their interactions. But this model appears to be incomplete and breaks down at high energies such as those that existed shortly after the Big Bang. This suggests new particles and interactions exist beyond what is accounted for in the Standard Model.

One mystery in this catalogue of particles and forces is that in the framework of the Standard Model, particles fit neatly into three categories with similar properties, yet very different
masses. The heaviest of these mass states have not existed naturally since shortly after the Big Bang. Physicists theorize that a rare, undiscovered combination of forces interacting on particles
could cause this mass variation. This unification of all known forces — the gravitational, electromagnetic, weak and strong forces - could hold sway over our world.

Mu2e will help test whether what is at work is a merging of all forces into one "grand unification" of forces that existed shortly after the Big Bang when the universe was full of heavy particles.
A muon that does not follow the traditional weak-force decay pattern into a lighter electron and two neutrinos, but converts wholly into an electron would signal the existence of new
particles or new forces - particles or forces beyond those included in the Standard Model. These new particles or forces would play a role in the unification process.

For efficiency reasons, physicists chose to study the conversion of a muon, the second heaviest building block of matter, and not the heavier tau particle's conversion. Muons live longer before they decay into lighter particles and are easier to produce in large quantities.

Seeing muon-to-electron conversion will be more difficult than finding a needle in a haystack and will require patience and vast quantities of muons.

In fact, theorists predict that this type of conversion happens so rarely that observing it would equate to finding one penny with a unique scratch on Abe Lincoln's head. That penny would be hidden in one of 234 piles of pristine pennies with each pile amounting to the 2010 U.S. budget of $3.55 trillion.

To increase the probability of seeing this rare subatomic process, physicists will generate huge numbers of muons by colliding a proton beam with a target.

During the experiment's initial two-year running period, it will produce about one quintillion muons, which is roughly the number of grains of sand on Earth's beaches.

This research strategy of producing vast quantities, or intense amounts, of particles rather than focusing on accelerating them to the highest energy marks studies on the Intensity Frontier. Particle physics research is divided into three broad approaches called frontiers. Studies on the Intensity Frontier require extreme machines, such as multi-megawatt proton accelerators that produce high-intensity beams, which generate large numbers of particles.

A second-phase, upgraded Mu2e experiment could utilize a proposed high-intensity upgrade to Fermilab's proton accelerator, that would increase the
production of muons by one to two orders of magnitude.

Further reading:

The Intensity Frontier is one of three research frontiers
in particle physics. Because muon-to-electron conversion is hypothesized to occur very rarely, scientists increase the chance of observing this
conversion by using accelerators to create a beam with a plenitude of muons. (Credit: HEPAP)

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The Mu2e experiment looks for muon particles to change in a different way than previously seen: the breakdown into a more stable electron particle
and jettison of the extra mass in the form of energy. When muons stop in aluminum they form atomic systems similar to the way electrons bind to the
nucleus in ordinary matter (left). A tiny fraction of the time the bound muon can convert to an electron that is ejected from the aluminum (right). (Credit: symmetry magazine)

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Muon-to-electron conversions are not only difficult to detect, like pulling a needle out of a haystack, but occur vary rarely.
It is as if the needle only existed in one out of hundreds of haystacks. Physicists increase the probability of observing the
conversion by increasing the number of muons, or haystacks, available for probing. Mu2e will have enough sensitivity to see a
muon transform to an electron (and nothing else) even if that only occurs in one out of 100 million billion muons.(Credit: Fermilab Education Office)

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Particle accelerators allow physicists to look farther and farther back in time, to revisit the high energies of the early universe
just after the Big Bang. Do the four forces that dictate the interactions of particles that we observe today - the gravitational,
electromagnetic, weak and strong forces - converge to a single unified force at ultra-high energy? The Mu2e experiment may provide
the first evidence for such unification of forces.(Credit: symmetry magazine)